Connectedness in Codimension One and the Non-S2 Locus

Abstract

We formulate a structural principle for finite S2-objects: coherent S2-sheaves and finitely generated graded S2-modules decompose canonically according to the connected components in codimension 1 of their support. This gives criteria relating indecomposability of S2-objects to connectedness in codimension 1 of their supports, and extends the Hochster--Huneke correspondences for complete local rings between connectedness in codimension 1, indecomposability of canonical modules, and localness of the S2-ifications. As a consequence, if A is a local ring admitting a canonical module ωA, there are canonical decompositions of both ωA and the S2-ification EndA(ωA) whose indecomposable summands are the canonical modules and S2-ifications of the quotient rings associated to the connected components in codimension 1. We then apply this viewpoint to the non-S2 locus. For A equidimensional and unmixed, this locus is naturally realized as SuppA C via the S2-ification sequence 0 A EndA(ωA) C 0. The natural map between deficiency modules K C+1(A) K C(C) identifies the canonical module K C(C) with the S2-hull of K C+1(A). Under suitable conditions, this allows codimension-1 connectedness of the non-S2 locus to be detected by the deficiency module K C+1(A). We illustrate the theory with examples and apply it to codimension 2 lattice ideals, obtaining connectedness-in-codimension-1 results for the non-S2 loci of certain toric and lattice rings.